A medical image processing apparatus according to an embodiment includes processing circuitry. The processing circuitry extracts, based on a first area that is an area to which radiation is emitted and a second area that is an area affected by the radiation emitted, a cross-section that satisfies a certain condition and that passes through two points, the first area and the second area being specified by volume data and the two points being a first point included in the first area and a second point included in the second area. The processing circuitry causes a display to present an image of the cross-section.
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11. The medical image processing apparatus, comprising:
processing circuitry configured to
extract, based on a first area that is an area to which radiation is emitted and a second area that is an area affected by the radiation emitted, a cross-section that satisfies a certain condition and that passes through two points, the first area and the second area being specified by volume data and the two points being a first point included in the first area and a second point included in the second area, and
cause a display to display an image of the cross-section, wherein
the second area is a union of a plurality of areas, and
the processing circuitry is further configured to extract a plurality of cross-sections.
1. A medical image processing apparatus, comprising:
processing circuitry configured to
extract, based on a first area that is an area to which radiation is emitted and a second area that is an area affected by the radiation emitted, a two-dimensional flat plane cross-section that satisfies a certain condition and that passes through two points, the first area and the second area being specified by volume data and the two points being a first point included in the first area and a second point included in the second area, and
cause a display to display an image of the cross-section,
wherein the certain condition used by the processing circuitry is a condition that a difference between (a) a distance between the two points and (b) a minimum value of a distance between a point included in the first area and a point included in the second area is less than a threshold.
9. A medical image processing apparatus, comprising:
processing circuitry configured to
extract, based on a first area that is an area to which radiation is emitted and a second area that is an area affected by the radiation emitted, a cross-section that satisfies a certain condition and that passes through two points, the first area and the second area being specified by volume data and the two points being a first point included in the first area and a second point included in the second area, and
cause a display to display an image of the cross-section, wherein the processing circuitry is further configured to
cause the display to display an axial cross-section extracted from the volume data on the display, and
extract, as the cross-section, a plane passing through the first point, the second point, and a point out of two points that have a shortest distance on the axial cross-section, the two points being a third point that is included in the first area and that is on the axial cross-section and a fourth point that is included in the second area and that is on the axial cross-section.
10. A medical image processing apparatus, comprising:
processing circuitry configured to
extract, based on a first area that is an area to which radiation is emitted and a second area that is an area affected by the radiation emitted, a cross-section that satisfies a certain condition and that passes through two points, the first area and the second area being specified by volume data and the two points being a first point included in the first area and a second point included in the second area, and
cause a display to display an image of the cross-section, wherein
the certain condition used by the processing circuitry is a condition that is determined in accordance with a difference between a distance between the two points and a minimum value of a distance between a point included in the first area and a point included in the second area and
the first point and the second point are points that are selected from the first area and the second area, respectively, such that a distance therebetween is minimum,
a fifth point and a sixth point are points that are selected from the first area and the second area such that a distance therebetween is second shortest, and
the processing circuitry is further configured to extract, as the cross-section, a plane passing through the first point, the second point, and the fifth point.
2. The medical image processing apparatus according to
3. The medical image processing apparatus according to
4. The medical image processing apparatus according to
5. The medical image processing apparatus according to
6. The medical image processing apparatus according to
7. The medical image processing apparatus according to
8. The medical image processing apparatus according to
cause the display to display an axial cross-section extracted from the volume data on the display, and
extract, as the two dimensional flat plane cross-section, a plane passing through the first point, the second point, and a third point that is non-co-linear with the first and second points.
12. The medical image processing apparatus according to
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This application is based upon and claims the benefit of priority from Japanese Patent Application No. 2016-099890, filed on May 18, 2016; the entire contents of which are incorporated herein by reference.
Embodiments described herein relate generally to a medical image processing apparatus.
In planning of radiation therapy to provide treatment by emitting radiation to the subject, it is preferable that the planning target volume (PTV) that is the area that is emitted with radiation, and the organ at risk (OAR) that is an area easily affected by radiation, such as superior pharyngeal constrictor muscle, are located apart by more than a certain distance.
However, for example, as the shape, size, or position of the tumor is different depending on the patient, the shape, size, or position of the PTV is different. Furthermore, the shape, size, or position of the OAR is different depending on the patient. Moreover, as the PTV is usually adjusted on the two-dimensional screen, it is sometimes not easy for users to know the distance between the PTV and the OAR in three dimensions.
A medical image processing apparatus according to an embodiment includes processing circuitry. The processing circuitry extracts, based on a first area that is an area to which radiation is emitted and a second area that is an area affected by the radiation emitted, a cross-section that satisfies a certain condition and that passes through two points, the first area and the second area being specified by volume data and the two points being a first point included in the first area and a second point included in the second area. The processing circuitry causes a display to present an image of the cross-section.
With reference to the attached drawings, a detailed explanation is given below of a (medical) image processing apparatus according to embodiments.
With reference to
An image processing apparatus 100 is connected to a modality apparatus 200, a storage device 220, and a display 250 via a network, whereby a medical-information management system is configured.
The modality apparatus 200 is a medical modality device, and for example it conducts examinations by taking images of the subject. Here, modality the generic term for, for example, medical devices and associated devices or accessories. Examples of the modality apparatus 200 include X-ray CT devices or general X-ray equipment.
The storage device 220 is a storage device that stores data, e.g., image data, which is acquired when the modality apparatus 200 conducts capturing on the subject. The storage device 220 may store the image data that is acquired from an external medical image information storage device as needed. The storage device 220 stores various types of data, such as capturing conditions. For example, the storage device 220 stores, as supplementary information of the image data, for example, the information about the PTV and the OAR. For example, the information about the PTV and the OAR is stored in the storage device 220 in the format that conforms to the Digital Imaging and Communications in Medicine (DICOM), which is known as the general standard of medical image information. The storage device 220 stores the sets of data in the form of, for example, a memory, an electronic file, or a database management system.
The storage device 220 is a semiconductor memory device, such as a random access memory (RAM) or a flash memory, a hard disk, an optical disk, or the like.
The display 250 is a display device that displays various types of information, such as image data, under the control of processing circuitry 150 of the image processing apparatus 100. The display 250 is a display device such as a liquid crystal display device.
The image processing apparatus 100 is a device that performs certain processes on the basis of the medical images, which are generated in accordance with capturing that is conducted on the subject by the modality apparatus 200 and which are stored in the storage device 220 as needed. The overall configuration of the image processing apparatus 100 is illustrated in
The image processing apparatus 100 includes the processing circuitry 150, memory circuitry 132, an input device 134, and a display device 135. Furthermore, the processing circuitry 150 includes an extraction function 150a, a control function 150b, a specifying function 150c, and an acquisition function 150d. Each of the extraction function 150a, the control function 150b, the specifying function 150c, and the acquisition function 150d is described later in detail.
According to the embodiment, each processing function, conducted by the extraction function 150a and the control function 150b, is stored in the memory circuitry 132 in the form of a program that is executable by the computer. The processing circuitry 150 is a processor that reads a program from the memory circuitry 132 and executes it, thereby performing the function that corresponds to each program. In other words, after having read each program, the processing circuitry 150 has each function that is illustrated within the processing circuitry 150 in
In other words, there may be a case where each of the above-described functions is configured as a program and each program is executed by single processing circuitry, or there may be a case where a specific function is implemented by a dedicated independent program execution circuitry.
Here, the extraction function 150a and the control function 150b included in the processing circuitry 150, are examples of an extracting unit and a control unit.
The term “processor” used in the above explanation means, for example, a central processing unit (CPU), a graphical processing unit (GPU), or a circuit, such as an application specific integrated circuit (ASIC), a programmable logic device (e.g., a simple programmable logic device (SPLD), a complex programmable logic device (CPLD), or a field programmable gate array (FPGA)). The processor reads and executes a program stored in the memory circuitry 132, to implement the function. Furthermore, a configuration may be such that, instead of storing programs in the memory circuitry 132, programs are directly installed in a circuit of the processor. In this case, the processor reads and executes the program installed in the circuit, to implement the function.
The memory circuitry 132 stores data, or the like involved in various processes that are performed by the image processing apparatus 100 as needed. For example, the memory circuitry 132 is a semiconductor memory device, such as a random access memory (RAM) or a flash memory, a hard disk, or an optical disk. Furthermore, the processes that are performed by the memory circuitry 132 in the processing circuitry 150 may be performed by the storage device 220 that is outside the image processing apparatus 100 instead.
The input device 134 receives inputs of various types of commands or information from the operator. The input device 134 is for example a pointing device, such as a mouse or a trackball, or an input device, such as a keyboard.
The display device 135 displays various types of information, such as image data, under the control of the control function 150b in the processing circuitry 150. The display device 135 is a display device, such as a liquid crystal display device. The processes that are performed by the display device 135 in the processing circuitry 150 may be performed by the display 250 that is outside the image processing apparatus 100 instead.
The programs that are executed by the image processing apparatus according to the above-described embodiment are provided by being previously installed in the ROM 320, or the like. Furthermore, the programs that are executed by the image processing apparatus according to the above-described embodiment may cause the computer to function as each unit of the above-described image processing apparatus. In the computer, the CPU 310 may load the programs from a storage medium readable by the computer, into the primary storages device and execute it.
Next, a brief explanation is given of the backgrounds according to the embodiment.
In the planning of radiation therapy to provide treatment by delivering radiation to the subject, it is preferable that the planning target volume (PTV) that is an area that is exposed to radiation, and the organ at risk (OAR) that is an area that is easily affected by radiation, such as superior pharyngeal constrictor muscle, are located apart by more than a certain distance. For example, if the OAR and the high dose (HD)-PTV that is the PTV that is exposed to high-dose radiation, are not located apart by more than a certain distance, side effects, such as a decrease in the body weight, are sometimes caused.
However, as the PTV is usually adjusted on the two-dimensional screen, it is sometimes not easy for users to know the distance between the PTV and the OAR in three dimensions. In addition, as the shape, size, and position of the tumor are different depending on the patient, the shape, size, and position of for example the PTV are different. Furthermore, the shape, size, and position of the OAR are also different depending on the patient. Moreover, for example, as the OAR sometimes looks very different depending on the capturing cross-section, it is sometimes difficult to check the distance between the PTV and the OAR in three dimensions.
Because of the above backgrounds, the image processing apparatus 100 according to the embodiment includes the extraction function 150a. The extraction function 150a extracts, from the volume data, an oblique cross-section that is the cross-sectional surface that makes it possible to easily determine the positional relationship between the OAR and the PTV. With the provision of this configuration, the image processing apparatus 100 according to the embodiment may support user's radiation therapy planning determinations.
Next, with reference to
First, the processing circuitry 150 uses the acquisition function 150d to acquire the volume data that is generated in accordance with the capturing result by the modality apparatus 200 and that is stored in the storage device 220. Then, the processing circuitry 150 uses the specifying function 150c to specify the first area (PTV) that is an area to which radiation is emitted, from the acquired volume data (Step S100). Furthermore, the processing circuitry 150 uses the specifying function 150c to specify the second area (OAR) that is the target area for which it is determined whether there is a presence or absence of effects of radiation, from the acquired volume data (Step S110).
Here, the information about the PTV and the OAR may be stored in the storage device 220 as the supplementary information related to medical images in association with the acquired volume data. In such a case, the processing circuitry 150 acquires information about the PTV and the OAR from the storage device 220 so as to specify the first area (PTV) and the second area (OAR). Furthermore, according to another example, the PTV and the OAR may be automatically generated by using for example a certain image processing technique on the volume data that is generated in accordance with the capturing result by the modality apparatus 200 and that is stored in the storage device 220. Furthermore, according to another example, the PTV and the OAR may be determined when an input of selection of an area is received from the user. Moreover, according to another example, the PTV and the OAR may be determined when an operation to select a certain PTV or OAR from the previously determined candidates is received from the user.
An example of a screen related to the above selection operation is illustrated in
For example, if an input of the message that the PTV is the PTV that is indicated by the identifier “high-dose (HD)-PTV 1” is received via the button 11a and the result is confirmed by the button 12, the processing circuitry 150 uses the specifying function 150c to specify the area of the PTV, which corresponds to the identifier “high-dose (HD)-PTV 1”, from the volume data. Furthermore, for example, if an input of the message that the OAR is the OAR that is indicated by the identifier “Superior_Constrictor” (superior pharyngeal constrictor muscle) is received via the button 11b and the result is confirmed by the button 12, the processing circuitry 150 uses the specifying function 150c to specify the area of the OAR, which corresponds to the identifier “Superior_Constrictor”, from the volume data. Furthermore, in a case where there is a plurality of OARs, if an input of the message that the second OAR is the OAR that is indicated by the identifier “Larynx” (pharynx) is received via the button 11c and the result is confirmed by the button 12, the specifying function 150c specifies the area of the OAR, which corresponds to the identifier “Larynx”, from the volume data.
Furthermore, by using the screen, the user may set/change the size, or the like, of the PTV or the OAR. Furthermore, by using the screen, the user may set/change number of target PTV or OAR.
The processing circuitry 150 uses the specifying function 150c to specify two points that are a first point included in the first area (the PTV 1) and a second point included in the second area (the OAR 2) and that satisfy a certain condition. Here, the certain condition is for example a condition that the difference between the minimum value of the distance between the point included in the first area and the point included in the second area and the distance between the two points is less than a certain threshold. In other words, for example, the processing circuitry 150 uses the specifying function 150c to specify the pair (the point 3 and the point 4 in
For example, this step is performed as described below. The processing circuitry 150 uses the extraction function 150a to extract the outline points (P1, P2, . . . , Pm in
The distance calculated here is for example the three-dimensional Euclidean distance; however, this is not a limitation on the embodiment, and other distances, such as Manhattan distance, may be used to specify the outline point with the minimum distance.
In
Next, the processing circuitry 150 uses the specifying function 150c to specify the third point that is the point included in the oblique cross-section 6 (Step S130).
This operation is illustrated in
For example, the processing circuitry 150 uses the control function 150b to display the axial cross-section 19 extracted from the volume data, on the display device 135. Furthermore, the processing circuitry 150 uses the specifying function 150c to specify the point 20 as the third point on the axial cross-section 19. Specifically, the processing circuitry 150 uses the specifying function 150c to specify the point 20 that is one point out of the two points (the point 20 and the point 21) which are the third point that is included in the first area (the PTV 1) and that is on the axial cross-section 19 and the fourth point that is included in the second area (the OAR 2) and that is on the axial cross-section 19, and which have the shortest distance on the axial cross-section.
Next, for example, the processing circuitry 150 uses the extraction function 150a to extract an oblique cross-section where the plane passes through the point 20 that is the third point that is specified at Step S130, the point 3 that is the first point, and the point 4 that is the second point (Step S140). For example, the processing circuitry 150 uses the extraction function 150a to derive the equation of the plane that passes through the given 3 points so as to extract the oblique cross-section. According to a different method, for example, the processing circuitry 150 rotates the plane 25 by a cross-section rotation angle ω with the straight line 5 as an axis such that the plane 25, which is the cross-section before a rotation operation is performed, includes the point 20, thereby extracting an oblique cross-section.
Next, with reference to
In
A sagittal cross-section 16b is a plain that is formed by the sagittal axis 14b and the axial axis 11a. A coronal cross-section 16c is a plain that is formed by the coronal axis 15a and the axial axis 11a. A sagittal cross-section 16e is a plain that is formed by the sagittal axis 14a and the axial axis 11b. A coronal cross-section 16f is a plain that is formed by the coronal axis 15b and the axial axis 11b.
A PTV 13a and a PTV 13b indicate a PTV area on the sagittal cross-section 16b. A PTV 13c indicate a PTV area on the coronal cross-section 16c. An OAR 12a indicates an OAR area on the coronal cross-section 16c. The PTV 13a indicates a PTV area on the oblique cross-section 16d. An OAR 12b indicates an OAR area on the oblique cross-section 16d. An OAR 12c indicates an OAR area on the sagittal cross-section 16e. A PTV 13e and a PTV 13f indicate a PTV area on the sagittal cross-section 16e. An OAR 12d indicates an OAR area on the coronal cross-section 16f. A PTV 13g indicates a PTV area on the coronal cross-section 16f.
For example, the processing circuitry 150 uses the extraction function 150a to extract the sagittal cross-section and the coronal cross-section (Step S150). For example, as illustrated in
Furthermore, as illustrated in the axial cross-section image of
Then, the processing circuitry 150 uses the extraction function 150a to extract the sagittal cross-section 16b, passing through the point 3 that is the first point, on the basis of the sagittal axis 14b and the axial axis 11a. The processing circuitry 150 uses the extraction function 150a to extract the coronal cross-section 16c, passing through the point 3 that is the first point, on the basis of the coronal axis 15a and the axial axis 11a. The processing circuitry 150 uses the extraction function 150a to extract the sagittal cross-section 16e, passing through the point 4 that is the second point, on the basis of the sagittal axis 14a and the axial axis 11b. The processing circuitry 150 uses the extraction function 150a to extract the coronal cross-section 16f, passing through the point 4 that is the second point, on the basis of the coronal axis 15b and the axial axis 11b.
Then, the processing circuitry 150 displays the oblique cross-section, extracted at Step S140, the sagittal cross-section and the coronal cross-section, extracted at Step S150, or the like, on the display device 135 (Step S160). For example, as illustrated in
The embodiment is not limited to the above-described example. At Step S130, the processing circuitry 150 may use a different method to specify the position of the third point so as to extract the oblique cross-section which is extracted at Step S140.
In
In this case, for example, the point 30 that is a fifth point, and a point 31 that is a sixth point, are points that are selected from the first area (the PTV 1) and the second area (the OAR 2), respectively, such that the distance is the second shortest distance. At Step S130, the processing circuitry 150 may use the point 30, which is the fifth point, as the third point in the flowchart of
Furthermore, “the distance between the point 30, which is the fifth point, and the point 31, which is the sixth point, is the second shortest distance” here means the specifics below. That is, the point 30, which is the fifth point, is one of the seventh points (e.g., P1, . . . , Pm in
Furthermore, another example for specifying the third point at Step S130 is illustrated in
In
In this case, at Step S130, the processing circuitry 150 uses the extraction function 150a to extract, as the third point, the point with the shortest distance from the second point from a plurality of points that has a certain positional relationship with the first point. Specifically, at Step S130, the processing circuitry 150 uses the extraction function 150a to extract, as the third point, the point that have the shortest distance from the point 4 that is the second point, from points P2, P3, . . . , P9, which have a positional relationship as a neighboring point with the point 3, which is the first point. Then, at Step S140, the processing circuitry 150 extracts, as the oblique cross-section 16d, a plane that passes through the point 3 that is the first point, the point 4 that is the second point, and the extracted third point.
Embodiments are not limited to the case described above. At Step S160, the processing circuitry 150 may cause a certain cross-section, such as the sagittal cross-section 16e, not to be displayed. In this case, the cross-section, which is not to be displayed, may be changed when for example the user uses a setting file.
As described above, with the medical image processing apparatus (the image processing apparatus 100) according to the first embodiment, users may easily know the three-dimensional positional relationship between the PTV and the OAR, for example, the distance between them. Thus, the image processing apparatus 100 may support radiation therapy planning determinations.
In the first embodiment, an explanation is primarily given of a case where there is the single PTV and the single OAR. In a second embodiment, an explanation is given of case where there are two or more PTVs or OARs by using
First, the processing circuitry 150 uses the user interface, which is illustrated in
This situation is explained in
Here, an example of the above-described certain condition is that, for example, the distance between the PTV 1a and the OAR 2a needs to be not less than sqrt (200) mm, the distance between the PTV 1a and the OAR 2b needs to be not less than sqrt (300) mm, the distance between the PTV 1b and the OAR 2a needs to be not less than sqrt (200) mm, and the distance between the PTV 1b and the OAR 2b needs to be not less than sqrt (300) mm. Furthermore, the distance between the point 6a and the point 6b is sqrt (150) mm, the distance between the point 6h and the point 6g is sqrt (1125) mm, the distance between the point 6d and the point 6c is sqrt (650) mm, and the distance between the point 6e and the point 6f is sqrt (200) mm. The OAR 2a is for example a superior pharyngeal constrictor muscle, and the OAR 2b is for example a parotid gland.
Here, in
Then, the processing circuitry 150 uses the extraction function 150a to extract the oblique cross-section 6 for each of the extracted pairs of PTV and OAR by using the same procedure as that is described in the first embodiment Step S210). If a plurality of areas constitutes the second area (OAR), the second area is a union of areas. If there is a plurality of pairs of PTV and OAR that is extracted at Step S200, the processing circuitry 150 uses the extraction function 150a to extract a plurality of oblique cross-sections. For instance, in the example of
Furthermore, at Step S210, the processing circuitry 150 may use the extraction function 150a to specify the third point that is the point other than the oblique axis explained in the first embodiment, on the basis of the positional relationship between the plurality of areas and, in accordance with the specification result, extract the oblique cross-section 6. The specific example in this case is illustrated in
In
The processing circuitry 150 uses the extraction function 150a to specify, as the third point, the point of the OAR with the shortest distance between the OAR and the point 41, which is the outline point at the side of the PTV 1, among the OARs (e.g., the OAR 40b, the OAR 40c) other than the OAR that corresponds to the pair of PTV and OAR with the shortest distance. For example, in
Then, the processing circuitry 150 determines whether the distance between the point 41 and the point 43 satisfies a certain condition. If the distance between the point 41 and the point 43 does not satisfy the certain condition (if it is less than the certain threshold), the processing circuitry 150 uses the extraction function 150a to extract, as the oblique cross-section 6, the plane that passes through the point 41, the point 42, and the point 43. In addition, if the distance between the point 41 and the point 43 does not satisfy the certain condition, the processing circuitry 150 may cause the extraction function 150a to extract, as another oblique cross-section, the plane that passes through the point 41, the point 42, and a single different point (e.g., the single point that is calculated by using the method described in the first embodiment). Conversely, if the distance between the point 41 and the point 43 satisfies the certain condition (if it is not less than the certain threshold), the processing circuitry 150 extracts, as the oblique cross-section 6, the plane that passes through the point 41, the point 42, and a single different point (e.g., the single point that is calculated by using the method described in the first embodiment).
Here, this is not a limitation on the embodiment. The processing circuitry 150 uses the extraction function 150a to specify, as the third point, the point of the OAR with the shortest distance between the PTV and the OAR among the OARs (e.g., the OAR 40b, the OAR 40c) other than the OAR that corresponds to the pair of PTV and OAR with the shortest distance. For instance, in
Then, the processing circuitry 150 uses the extraction function 150a to extract the sagittal cross-section and the coronal cross-section with regard to each of the extracted pairs (Step S220). This situation is illustrated in
In
In the same manner as in the first embodiment, the processing circuitry 150 uses the extraction function 150a to extract the sagittal cross-section and the coronal cross-section on the basis of the axial axis 51 that passes through the point 41. Furthermore, the processing circuitry 150 uses the extraction function 150a to extract the sagittal cross-section and the coronal cross-section on the basis of the axial axis 52 that passes through the point 42. In addition, according to the second embodiment, in consideration of a plurality of OARs, the sagittal cross-section and the coronal cross-section may be extracted on the basis of the axial axis 53 that passes through the point 43 on the OAR 40b, which is the OAR other than the OAR that corresponds to the pair of PTV and OAR with the shortest distance, by using the same procedure as that is described in the first embodiment.
Then, the processing circuitry 150 uses the display device 135 to display the oblique cross-section that is extracted at Step S210 and the sagittal cross-section and the coronal cross-section that are extracted at Step S220. Here, if the distance of PTV and OAR in pair is less than the threshold, the processing circuitry 150 may display certain information on the display device 135. For example, if the distance between PTV and OAR in pair is less than the threshold, the processing circuitry 150 changes the color of the image title and displays it on the display device 135. Furthermore, according to another example, if the distance between PTV and OAR in pair is less than the threshold, the processing circuitry 150 displays the message on the display device 135 by using texts. This example is illustrated in
In
The PTV 1 indicates a PTV. The OAR 2 indicates an OAR. The PTV 13a, the PTV 13b, the PTV 13e, and the PTV 13f indicate a PTV area on the sagittal plain. The OAR 12c indicates an OAR area on the sagittal plain. The PTV 13c and the PTV 13g indicate a PTV area on the coronal plain. The OAR 12a and the OAR 12c indicate an OAR area on the coronal plain. The PTV 13a indicates a PTV area on the oblique cross-section. The OAR 12b indicates an OAR area on the oblique cross-section. The images of the cross-sections are the same as those in
For example, if the currently set PTV-OAR distance is 1.2 cm and it is less than 1.6 cm, which is the reference value, the processing circuitry 150 uses the control function 150b to display “the currently set PTV-OAR margin is 1.2 cm that is less than 1.6 cm!” through the display area 60 on the display device 135. Furthermore, at this time, the processing circuitry 150 uses the control function 150b to change the display color on the associated display areas 61a to 61f from “black” during the normal time to “red” and display it on the display device 135.
Furthermore, with regard to a plurality of pairs of PTV and OAR, if the distance between PTV and OAR in pair is less than the threshold, the processing circuitry 150 uses the control function 150b to display a certain warning on the display device 135 via the display area 60 with respect to each of the pairs of PTV and OAR. For instance, in the example of
As described above, with the medical image processing apparatus (the image processing apparatus 100) according the second embodiment, even if there is a plurality of PTVs or OARs, it is possible that users easily know the three-dimensional positional relationship between the PTV and the OAR, for example, the distance between them. Thus, the image processing apparatus 100 may support radiation therapy planning determinations more efficiently.
In the second embodiment, an explanation is given of a case where there is a plurality of PTVs or OARs. In a third embodiment, an explanation is given of a case where a filtering process, which is a process to cause unnecessary cross-sections not to be displayed, is performed by using
The processing circuitry 150 performs the operations at Steps S200 to S220 of
The filter determination process is explained with reference to
In
In
In
With reference to
Furthermore, in the case of the upper diagram (Case A) of
Furthermore, in the case of the lower diagram (Case B) of
In the case of the upper diagram (Case A) of
Furthermore, in the case of the lower diagram (Case B) of
Then, the processing circuitry 150 uses the control function 150b to display, on the display device 135, a cross-section other than the cross-section that is determined not to be displayed during the filter determination process at Step S300 among the cross-sections that are extracted at Step S210 and Step S220 (Step S310). In other words, the processing circuitry 150 uses the control function 150b to control the display device 135 so as to perform the filter process that is a process to hide cross-section images that do not include at least any one of the first area (PTV) and the second area (OAR). Then, on the basis of the cross-section image that is displayed on the display device 135, the user adjusts the PTV. Thus, the image processing apparatus 100 may support radiation therapy planning determinations.
Furthermore, embodiments are not limited to this situation.
At Step S300, if there is a plurality of PTVs or OARs, the processing circuitry 150 may perform the filter determination process by considering the positional relationship between the PTV and the OAR other than the PTV and the OAR that corresponds to the pair of the PTV and the OAR with the shortest distance. An example of the process in such a case is illustrated in
In
First, consideration is given to a case where the positional relationship between the PTV and the OAR other than the pair (the PTV 96b and the OAR 95a) with the shortest distance is not considered. In such a case, with regard to the sagittal cross-section with the sagittal axis that is indicated by the dotted line in
Furthermore, the embodiment is not limited to the above-described example. The processing circuitry 150 may receive an input as to whether the filter process is performed from the user. This display screen is illustrated in
If the user clicks the button 99a and the button before Step S300, the processing circuitry 150 receives an input of the message that filtering is conducted. In such a case, the processing circuitry 150 performs the operations at Step S220 and Step S230. Conversely, if the user clicks the button 99b and the button 99c, the processing circuitry 150 receives an input of the message that filtering is not conducted. In such a case, the processing circuitry 150 does not perform the operations at Step S220 and Step S230.
Furthermore, the processing circuitry 150 may use the control function 150b to determine whether the filtering process is performed on the basis of the information that is set by a setting file that is generated in advance.
Moreover, at Step S300, the processing circuitry 150 may use the control function 150b to determine that the cross-section is not to be displayed not only in a case where either one of the PTV and the OAR appears (they do not overlap) but also in a case where the area of one of the PTV and the OAR is small (if the degree of overlap is small).
(Program)
Commands that are defined in the steps of the process described in the above-described embodiment may be executed on the basis of software programs. A general-purpose computer system previously stores the program and reads program so that the same advantage as that is produced by the image processing apparatus 100 according to the above-described embodiment may be achieved. The commands that are defined according to the above-described embodiment are recorded as programs executable by the computer in a magnetic disk (flexible disk, hard disk, or the like), an optical disk (CD-ROM, CD-R, CD-RW, DVD-ROM, DVD±R, DVD±RW, or the like), a semiconductor memory, or a similar recording medium. The storage medium may have any storage format as long as it is readable by the computer or the installed system. The computer reads a program from the recording medium and, in accordance with the program, causes the CPU to execute the command that is defined by the program, whereby the same operation as that of the image processing apparatus 100 according to the above-described embodiment may be conducted. It is obvious that, if the computer acquires or reads a program, it may acquire or read a program via a network.
Furthermore, part of each of the processes for implementing the above-described embodiment may be performed by the operating system (OS), operating on the computer, middle ware (MW), such as database management software or a network, or the like, on the basis of the command of the program that is installed into the computer or the installed system from the storage medium.
Furthermore, the storage medium des not only a medium separate from a computer or an installed system but also a storage medium that downloads and stores or temporarily stores a program that is transmitted via a local area network (LAN), the Internet, or the like.
Furthermore, the number of storage media is not limited to one, and the storage medium according to the embodiment includes a case where the process according to the above-described embodiment is performed by using multiple media; thus, the medium may have any configuration.
Furthermore, the image processing apparatus 100 according to the embodiment performs each of the processes according to the above-described embodiment on the basis of the program that is stored in a storage medium, and it may have any configuration, e.g., the single device such as a personal computer or a microcomputer, or a system in which multiple devices are connected via a network.
Furthermore, the computer according to the embodiment includes not only a personal computer but also an arithmetic processing device, a microcomputer, or the like which is included in an information processing device, and it is a generic term for devices and apparatuses that are capable of performing the function according to the embodiment by using programs.
As described above, with the image processing apparatus 100 according to at least one of the embodiments, it is possible to support radiation therapy planning determinations.
While certain embodiments have been described, these embodiments have been presented by way of example only, and are not intended to limit the scope of the inventions. Indeed, the novel embodiments described herein may be embodied in a variety of other forms; furthermore, various omissions, substitutions and changes in the form of the embodiments described herein may be made without departing from the spirit of the inventions. The accompanying claims and their equivalents are intended to cover such forms or modifications as would fall within the scope and spirit of the inventions.
Kano, Yusuke, Piao, Longxun, Murakami, Kazuhisa, Ozaki, Masahiro, Sakaue, Kousuke, Sugiyama, Shinya
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